Dynamics of a large, restless, rhyolitic magma system at Laguna del Maule, southern Andes, Chile


Back to previous page
Authors: Singer, B., Andersen, N., Le Mével, H., Feigl, K., DeMets, C., Tikoff, B., Thurber, C., Jicha, B., Cardona, C., Córdova, L., Gil, F., Unsworth, M., Williams-Jones, G., Miller, C., Fierstein, J., Hildreth, W., Vazquez, J
Year: 2014
Journal: GSA Today 24: 4-10   Article Link (DOI)
Title: Dynamics of a large, restless, rhyolitic magma system at Laguna del Maule, southern Andes, Chile
Abstract: Explosive eruptions of large-volume rhyolitic magma systems
are common in the geologic record and pose a major potential
threat to society. Unlike other natural hazards, such as earthquakes and tsunamis, a large rhyolitic volcano may provide
warning signs long before a caldera-forming eruption occurs.
Yet, these signs—and what they imply about magma-crust
dynamics—are not well known. This is because we have learned
how these systems form, grow, and erupt mainly from the study of
ash flow tuffs deposited tens to hundreds of thousands of years
ago or more, or from the geophysical imaging of the unerupted
portions of the reservoirs beneath the associated calderas. The
Laguna del Maule Volcanic Field, Chile, includes an unusually
large and recent concentration of silicic eruptions. Since 2007, the
crust there has been inflating at an astonishing rate of at least
25 cm/yr. This unique opportunity to investigate the dynamics of
a large rhyolitic system while magma migration, reservoir growth,
and crustal deformation are actively under way is stimulating a
new international collaboration. Findings thus far lead to the
hypothesis that the silicic vents have tapped an extensive layer of crystal-poor, rhyolitic melt that began to form atop a magmatic
mush zone that was established by ca. 20 ka with a renewed phase
of rhyolite eruptions during the Holocene. Modeling of surface
deformation, magnetotelluric data, and gravity changes suggest
that magma is currently intruding at a depth of ~5 km. The next
phase of this investigation seeks to enlarge the sets of geophysical and geochemical data and to use these observations in numerical models of system dynamics.
Back to previous page
 


Departmental members may update their publication list.